Authors: Amira Val Baker, Máté Csanád, Nicolas Fellas, Nour Atassi, Paul Oomen

Abstract: Standing waves formed on a vibrating fluid layer when a critical amplitude is applied are known as Faraday waves. The morphology of the observed phenomena is dependent on both the frequency of vibration and the boundary conditions. To understand the degree of this dependency, as well as any internal or external factors, we investigated the resonant phenomena observed in a circular cuvette for a range of frequencies. We find the symmetry fold is dependent on both the driving frequency and the amplitude. However, variance was consistently observed which showed no significant dependence on internal or external factors. We discuss possible causes for this variance and potential future research.

Disciplines: Physics Physical Sciences and Mathematics Statistical, Nonlinear, and Soft Matter Physics.

Keywords: Cymatics, Environmental Dependence, Faraday Waves, Nonlinear Dynamics, Pattern Morphology, Reproducibility, Resonant Phenomena, Vibrational Modes.

Citations:

APA: Val Baker, A., Csanád, M., Fellas, N., Atassi, N., & Oomen, P. (2023, October 9). Resonant Phenomena of Faraday Waves: Reproducibility. https://doi.org/10.31219/osf.io/dsvgc

MLA: Val Baker, Amira, et al. “Resonant Phenomena of Faraday Waves: Reproducibility.” OSF Preprints, 9 Oct. 2023. Web.

Chicago: Val Baker, Amira, Máté Csanád, Nicolas Fellas, Nour Atassi, and Paul Oomen. 2023. “Resonant Phenomena of Faraday Waves: Reproducibility.” OSF Preprints. October 9. doi:10.31219/osf.io/dsvgc.

IEEE: [1] A. Val Baker, M. Csanád, N. Fellas, N. Atassi and P. Oomen, “Resonant Phenomena of Faraday Waves: Reproducibility”, 09-Oct-2023. [Online]. Available: osf.io/dsvgc.

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